DE3327025A1 - Double ladder - Google Patents

Abstract

The double ladder is provided with two pairs of uprights which are interconnected in an articulated manner and has at least two steps which are interconnected by connecting rods. Provided on one step is a positive guide in the form of a slot for a guide part. A stop lies in front of this step in the direction of loading of the step, as a result of which the steps are secured against pivoting during loading. The stop moreover prevents the pairs of uprights being pivoted in a direction towards one another during displacement of the folded-out double ladder.

Description

Stepladder

The invention relates to a stepladder according to the preamble of the claim 1.

In this known stepladder, the steps are through two handlebars articulated together, which in the working position of the stepladder to the The bars of the first pair of bars are in contact. On the handlebars is one leg of a two-armed Lever articulated, the other leg of which in one along the spars of the second pair of spars running groove is performed. To prevent the stepladder from folding up unintentionally to prevent the two-armed lever by means of a screw and a spring washer frictionally fasten to the bars of the first pair of bars. With this frictional connection but cannot be reliably prevented from accidentally collapsing the stepladder.

In this way, the frictional engagement can be eliminated by loading the steps so that the two pairs of bars in the direction of each other due to the tread load sway. Since the frictional engagement must be adjusted by hand, there is There is a risk that this setting will be forgotten, so that the stepladder is no longer against unintentional folding is secured.

The invention is based on the object of the generic stepladder to be designed in such a way that unintentional collapsing is impossible and the protection against unintentional collapsing by loading the steps still is reinforced.

This object is achieved according to the invention in the step ladder of the generic type solved with the characterizing features of claim 1.

When the stepladder according to the invention is unfolded, the guide part of the second pair of stiles in the forced guidance of the step, whereby the Steps automatically move into their horizontal step position when unfolded. If the steps are loaded, this prevents the step in the direction of the load Stop lying in front of them that the steps swivel back and thereby the The stepladder folds up. Even if the stepladder is in working position is moved on the floor, the stop prevents unintentional folding. This means that there is no risk of the steps being accidentally moved swiveled back and then swiveled completely into their rest position when loaded will. There is a risk of accidents when working with the stepladder according to the invention therefore considerably reduced, since they are only then collapsed into their storage position if so desired by the operator. For locking the stepladder are in the working position as a result of the stop and the forced guidance No additional securing parts in the step, such as locking hooks and like that, necessary. This not only has advantages in terms of manufacturing technology, but also simplifies the handling of the stepladder significantly, so that they can also be used by less trained people can be set up easily and safely.

Further features of the invention emerge from the further claims, the description and the drawings.

The invention is illustrated by some of the drawings Embodiments explained in more detail. 1 shows a side view of a device according to the invention The stepladder in the working position, FIG. 2 the stepladder according to FIG. 1 in a front view, 3 shows the stepladder according to FIG. 1 in a position during the folding up, 4 shows the stepladder in the folded position, FIG. 5 is a side view of the folded stepladder according to FIG. 4, FIGS. 6 to 8, each in an enlarged view Representation of different embodiments of steps according to the invention Stepladder, FIG. 9 the stepladder according to FIG. 3 in the working position.

The stepladder has two pairs of stiles 1, 2, of which in Fig.

1 only one spar is shown. In Fig. 2 are the two Spars 3, 4 of the pair of spars 2 can be seen. The spars of the spar pairs are at the top End pivotally connected to each other, so that the stepladder from the working position (Fig. 1) can be folded into the storage position (Fig. 4). At the spars of the pair of spars 1 are spaced one above the other two steps 5 and 6 hinged, which extend between the spars of the spar pair and through an axle 7 and 8 are each articulated to these spars. The spars 3, 4 des Pair of spars 2 are near their lower end by a Cross rod 9 connected to one another, which gives the pair of spars 2 sufficient torsional rigidity gives. Seen in the front view according to FIG. 2, the bars of the two pairs of bars are located 1, 2 are each congruent, so that they are immediately in the storage position according to FIG lie one behind the other, so that the spar pairs in the direction of the axis of the crossbar 9 take up little space.

The steps 5, 6 extend in the area between the spars each pair of spars, seen in front view, and are preferably made for weight reasons made of an aluminum sheet that angled downwards at the ends facing the bars Has cheeks 10 and 11. They are interspersed with axes 7 and 8, which too enforce the bars of the pair of bars 1. The upper step 5 is as below will be explained in more detail, also connected to the pair of spars 2. The cheeks 11 of the lower step 6 are supported by a second, parallel to the axis 8 Axis 14 passes through, on whose ends protruding beyond the cheeks links 12, 13 are stored. The handlebars, seen in the front view according to FIG. 2, lie between the bars of each pair of bars and the cheeks 10, 11 of the steps 5, 6. The upper one The end of the link 12, 13 is mounted on an axis 15 which is parallel to the axis 14 runs and the cheeks 10 of the upper step 5 penetrates. The handlebars 12, 13 lie parallel to the spars of the spar pairs 1, 2 and to the cheeks 10, 11 of the Steps 5, 6. The lower step 6 is on the handlebars 12, 13 with the upper Step 5 connected in such a way that the lower step when folding or Inevitably unfold into their storage position or into their working position is pivoted.

The stepladder can also have more than two steps, if the spars are correspondingly long (Fig. 3). In this faied also the other steps 6 'through the handlebars 12, 13 with each other and with the upper step 5 in the described Way articulated together.

In the working position (Fig. 1) the links 12, 13 are in side view seen, parallel to the spars of the pair of spars 1.

So that when the stepladder is folded up or down the steps 5, 6 are automatically pivoted into the corresponding positions, is at least one cheek 10, but preferably both cheeks 10, are provided with a positive guide 16, in which at least one guide part 17 is guided, which is provided on the second pair of bars 2 is. The guide part 17 is a rod in the embodiment, which is attached to the two Spars 3, 4 of the pair of spars 2 is attached. As a result, the guide part also carries contributes to the torsional stiffness of the stepladder. Also the axes 7 and 8 with which the steps 5, 6 are hinged to the pair of bars 1, increase the torsional stiffness, because they connect the two bars of the pair of bars 1 with each other. The upper step 5 a stop 19 located in front of it in the direction of tread load 18 is assigned, on which the step rests in the working position (Fig. 1). The stop 19 is attached to the pair of bars 2 and is preferably through one of the bars 3, 4 of this Pair of spars connecting axis formed. As a result, this stop 19 also the torsional stiffness of the stepladder increases.

The positive guide 16 runs over at least part of its length contrary to the tread load direction 18. This ruled out that under load the stepladder collapses even if the Have not yet reached their working position. So should the Pairs of spars have inadvertently not been swung apart far enough, then the stepladder is not folded up when stepping on the steps, but pushed apart.

The constrained guide 16 is a slot in which the guide part 17 slides. Since preferably in both cheeks 10 of the step, which are angled downwards at right angles 5 a positive guide is provided and the guide part 17 by an axis is formed, it intervenes simultaneously in both forced guidance, so that in simpler Way a synchronism of the two spars 3, 4 when opening and closing the stepladder is achieved. The guide part 17 extending through the slot 16 ensures a reliable pivoting of the step 5.

When the stepladder is folded up from the working position according to FIG is to be, the upper step 5 is raised, whereby the stop 19 of the step is released. Since the step 5 swivels upwards around the axis 7, is inevitably achieved via the guide part 17 that the spar pairs 1, 2 in Pivot direction to each other. At the same time via the links 12, 13 the lower Step 6 also swiveled upwards about axis 8. Fig. 3 shows an intermediate position when folding up the stepladder.

In this illustrated embodiment, there are three steps provided, which are articulated to one another by the links 12, 13. the 4 and 5 show the folded-up storage position of the stepladder. The two pairs of spars 1, 2 are in this position parallel to one another and one behind the other. The steps 5, 6 are pivoted about their axes 7, 8 so far up that she with their treads 20, 21 are vertical. The width of the Cheeks 10, 11 is smaller than the total width of the pairs of bars, so that the cheeks are completely covered by the spar pairs (Fig. 4). The handlebars 12, 13 are laterally covered by the pairs of spars. The stepladder has thus in the Storage position only a small width, so that it can also be conveniently parked there where there is little space. Should the stepladder go back to the Working position are unfolded, only the pair of spars 2 is after pivoted outside, with the positive guide 16 and the guide part 17 and about the handlebars 12, 13 the steps 5, 6 down into the horizontal working position be swiveled.

The positive guide 16 designed as a slot extends at least in its end region 22 obliquely upwards in the direction of the step side 20 of the step 5. This will certainly prevent the step back from falling under load can pivot into its vertical position. The inclined end region 22 of the The slot 16 goes near the lower edge 23 of the cheeks 10 in parallel to it extending portion 24 over, in which the guide part 17 in the storage position the stepladder lies (Fig. 4).

The step 5 is on its edge 25 facing the stop 19 provided with a recess 26 for the stop.

In the working position, the stop 19 lies in this recess 26, which provides additional security against unintentional pivoting back of the Step 5 is reached. The recess 26 is on the one from the articulation point 7 provided on the pair of spars 1 facing away from the end of the step 5 and to the adjacent Narrow side 25 open. The stop 19 can therefore when pivoting the step 5 into the working position without difficulty in the recess 26 reach. It has a contact surface 27 for the stop 19, which is angled to each other by two lying surface sections 28 and 29 is formed. The stop 19 is in the stop position (Fig. 1 and 6) on both surface sections 28 and 29. If step 5 loaded on their tread 20, then the force occurring here is over the surface section 28 is transferred to the stop 19 and from there to the pair of bars 2. The stop 19 forms a support for the step 5. The guide part 17 therefore does not need a force transmission function, only the management function to take over. For this reason it is also in the working position of step 5 at a distance from the end of the slot 16. The other surface section 29 is then particularly stressed when the stepladder is moved in the unfolded position should be.

Then the stop 19 rests against this surface section and prevents it in that the pair of spars 2 accidentally pivoted in the direction of the pair of spars 1 will. The inclined position of the end area 22 of the slot 16 and the course of the surface section 29 are of course coordinated so that the step 5 from the 6 pivoted upward into its vertical storage position can be. The two surface sections 28, which are at right angles to one another, 29 are continuously curved into one another. They also form the edges of the recess 26, each approximately at right angles to the front edge 25 and the lower edge 23 of the cheek 10.

In the embodiment according to FIG. 7, which is designed as a slot Positive guide 16a upwards over its entire length in the direction of the step side 20 step 5 is steadily curved. This allows the step to be even and steadily Swivel into its two end positions, which makes it easier to handle the stepladder will. The slot 16a is, as in the previous embodiment, over his entire length is the same width and is penetrated by the guide part 17 in the slot is sliding. So that the step 5 from the stop 19 in such a design of the slot 16a comes free, the surface sections 28a, 29a of the recess lie 26a at an obtuse angle to one another. Otherwise, the recess 26a has the same design as in the previous embodiment.

Fig. 8 shows an embodiment in which the slot 16b over its entire length obliquely upwards and straight in the direction of the step side 20 of the step 5 runs. The recess 26b points at the transition between the two surface sections 28b, 29b a groove 30 for the stop 19, in which it is in the working position the stepladder lies. This ensures a particularly secure locking of the step 5 reached in the working position of the stepladder.

In order for the step 5 to come free from the stop 19, it must Pair of spars 2 are initially pivoted away from the other pair of spars 1 that the stop 19 comes free from the recess 30. Only then can step 5 be pivoted upwards into their storage position. So that the pair of bars 2 can perform this additional pivoting movement, the guide part 17 is in the Working position with a corresponding distance from the end of the slot 16b (see. Fig. 8th).

The stepladder is characterized by a structurally simple structure and easy handling. It can also be used by less experienced people Easily set up and lock securely, without the need for additional locking parts, such as hooks to be hung and the like are. Despite With its structurally simple design, the stepladder guarantees a high level of stability and absolute protection against unintentional collapsing. The stepladder can easily be moved on the floor in the unfolded position without that it must be feared that the spar pairs accidentally in the direction of zueinanier swiveled and then folded up when the steps are loaded will.

As shown in FIG. 9, the steps 5, 6, 6 'can in this way be hinged on the pair of spars 1 that you stood on 31 increases downwards. Under The protrusion is the distance between the axis of rotation 7, 8, 8 ′ and the free end 32 to understand the steps. The increasing overhang makes it accessible the steps significantly improved. However, the leverage increases with increasing survived too, which would cause the steps to swing up. this will but absolutely sure prevented that the positive guide 16 at least in their The end area runs counter to the tread load direction 18. Via the guide part 17 the spar pairs 1, 2 in cooperation with the forced guidance even in the direction pressed to their spread position, which increases the stability of the stepladder is increased. The supernatant described can be used in all of the described embodiments to be available.

Claims (16)

Claims G stepladder with two hingedly connected Pairs of stiles, with at least two steps, which are in the working position of the stepladder lie at least approximately horizontally and pivot with the first pair of spars are connected, and with at least one handlebar to which the treads are hinged are, characterized in that one of the steps (5, 6) has a Forced guidance (16, 16a, 16b) for at least one guide part (17) of the second pair of bars (2) is provided, and that this step has at least one in the tread load direction (18) in front of her lying stop (19) is assigned. 2. A step ladder according to claim 1, characterized in that the stop (19) provided on the second pair of bars (2), preferably by one of the bars (3, 4) this spar pair connecting axis is formed. 3. step ladder, in particular according to claim 1 or 2, characterized in that that the positive guide (16, 16a, 16b) over at least part of its length against Step load direction (18) runs. 4. A step ladder according to one of claims 1 to 3, characterized in that that the positive guide (16, 16a, 16b) is a slot in which the guide part (17) the second Pair of spars (2) slides. 5. stepladder according to claim 4, characterized in that the slot (16, 16a, 16b) at least in its one end region (22) obliquely upwards in the direction runs on a step side (20) of the step (5). 6. A step ladder according to claim 4 or 5, characterized in that the slot (16a) over its entire length upwards towards the step side (20) of the step (5) is curved. 7. A step ladder according to claim 4 or 5, characterized in that the slot (16b) over its entire length obliquely upwards and straight in the direction runs on the step side (20) of the step (5). 8. A step ladder according to one of claims 1 to 7, characterized in that that the step has a recess on its edge (25) adjacent to the stop (19) (26, 26a, 26b) is provided for the stop. 9. A step ladder according to claim 8, characterized in that the recess (26, 26a, 26b) on the one facing away from the articulation point (7) on the first pair of bars (1) End of the step (5l is provided. 10. A step ladder according to one of claims 1 to 9, characterized in that that the recess (26, 26a, 26b) to the adjacent narrow side (25) of the step (5) is open. 11. A step ladder according to one of claims 1 to 10, characterized in that that the recess (26, 26a, 26b) has a contact surface (27) for the stop (19) has that by two surface sections at an angle to one another (.28, 29; 28a, 29a; 28b, 29b) is formed. 12. A step ladder according to claim 11, characterized in that the surface sections (28, 29; 28a, 29a; 28b, 29b) form the edges of the recess (26, 26a, 26b). 13. A step ladder according to any one of claims 1 to 5 and 8 to 12, characterized characterized in that the surface sections (28, 29) are at right angles to one another. 14. A step ladder according to any one of claims 1 to 5 and 8 to 12, characterized characterized in that the surface sections (28a, 29a; 28b, 29b) are at obtuse angles to one another lie. 15. A step ladder according to one of claims 1 to 5 and 8 to 12 and 14, characterized in that at the transition between the two surface sections (28b, 29b) a groove (30) is provided for the stop (19). 16. A step ladder according to one of claims 1 to 15, in the case of both sides the treads each have a handlebar, characterized in that the Guide part (17) one of the two bars (3, 4) of the second pair of bars (2) rigid interconnecting axis is.